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gf-core/src/compiler/Data/Binary/Put.hs

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-----------------------------------------------------------------------------
-- |
-- Module : Data.Binary.Put
-- Copyright : Lennart Kolmodin
-- License : BSD3-style (see LICENSE)
--
-- Maintainer : Lennart Kolmodin <kolmodin@dtek.chalmers.se>
-- Stability : stable
-- Portability : Portable to Hugs and GHC. Requires MPTCs
--
-- The Put monad. A monad for efficiently constructing lazy bytestrings.
--
-----------------------------------------------------------------------------
module Data.Binary.Put (
-- * The Put type
Put
, PutM(..)
, runPut
, runPutM
, putBuilder
, execPut
-- * Flushing the implicit parse state
, flush
-- * Primitives
, putWord8
, putByteString
, putLazyByteString
-- * Big-endian primitives
, putWord16be
, putWord32be
, putWord64be
-- * Little-endian primitives
, putWord16le
, putWord32le
, putWord64le
-- * Host-endian, unaligned writes
, putWordhost -- :: Word -> Put
, putWord16host -- :: Word16 -> Put
, putWord32host -- :: Word32 -> Put
, putWord64host -- :: Word64 -> Put
) where
import Data.Monoid
import Data.Binary.Builder (Builder, toLazyByteString)
import qualified Data.Binary.Builder as B
import Data.Word
import qualified Data.ByteString as S
import qualified Data.ByteString.Lazy as L
import Control.Applicative
------------------------------------------------------------------------
-- XXX Strict in buffer only.
data PairS a = PairS a {-UNPACK-}!Builder
sndS :: PairS a -> Builder
sndS (PairS _ b) = b
-- | The PutM type. A Writer monad over the efficient Builder monoid.
newtype PutM a = Put { unPut :: PairS a }
-- | Put merely lifts Builder into a Writer monad, applied to ().
type Put = PutM ()
instance Functor PutM where
fmap f m = Put $ let PairS a w = unPut m in PairS (f a) w
{-# INLINE fmap #-}
instance Applicative PutM where
pure = return
m <*> k = Put $
let PairS f w = unPut m
PairS x w' = unPut k
in PairS (f x) (w `mappend` w')
-- Standard Writer monad, with aggressive inlining
instance Monad PutM where
return a = Put $ PairS a mempty
{-# INLINE return #-}
m >>= k = Put $
let PairS a w = unPut m
PairS b w' = unPut (k a)
in PairS b (w `mappend` w')
{-# INLINE (>>=) #-}
m >> k = Put $
let PairS _ w = unPut m
PairS b w' = unPut k
in PairS b (w `mappend` w')
{-# INLINE (>>) #-}
tell :: Builder -> Put
tell b = Put $ PairS () b
{-# INLINE tell #-}
putBuilder :: Builder -> Put
putBuilder = tell
{-# INLINE putBuilder #-}
-- | Run the 'Put' monad
execPut :: PutM a -> Builder
execPut = sndS . unPut
{-# INLINE execPut #-}
-- | Run the 'Put' monad with a serialiser
runPut :: Put -> L.ByteString
runPut = toLazyByteString . sndS . unPut
{-# INLINE runPut #-}
-- | Run the 'Put' monad with a serialiser and get its result
runPutM :: PutM a -> (a, L.ByteString)
runPutM (Put (PairS f s)) = (f, toLazyByteString s)
{-# INLINE runPutM #-}
------------------------------------------------------------------------
-- | Pop the ByteString we have constructed so far, if any, yielding a
-- new chunk in the result ByteString.
flush :: Put
flush = tell B.flush
{-# INLINE flush #-}
-- | Efficiently write a byte into the output buffer
putWord8 :: Word8 -> Put
putWord8 = tell . B.singleton
{-# INLINE putWord8 #-}
-- | An efficient primitive to write a strict ByteString into the output buffer.
-- It flushes the current buffer, and writes the argument into a new chunk.
putByteString :: S.ByteString -> Put
putByteString = tell . B.fromByteString
{-# INLINE putByteString #-}
-- | Write a lazy ByteString efficiently, simply appending the lazy
-- ByteString chunks to the output buffer
putLazyByteString :: L.ByteString -> Put
putLazyByteString = tell . B.fromLazyByteString
{-# INLINE putLazyByteString #-}
-- | Write a Word16 in big endian format
putWord16be :: Word16 -> Put
putWord16be = tell . B.putWord16be
{-# INLINE putWord16be #-}
-- | Write a Word16 in little endian format
putWord16le :: Word16 -> Put
putWord16le = tell . B.putWord16le
{-# INLINE putWord16le #-}
-- | Write a Word32 in big endian format
putWord32be :: Word32 -> Put
putWord32be = tell . B.putWord32be
{-# INLINE putWord32be #-}
-- | Write a Word32 in little endian format
putWord32le :: Word32 -> Put
putWord32le = tell . B.putWord32le
{-# INLINE putWord32le #-}
-- | Write a Word64 in big endian format
putWord64be :: Word64 -> Put
putWord64be = tell . B.putWord64be
{-# INLINE putWord64be #-}
-- | Write a Word64 in little endian format
putWord64le :: Word64 -> Put
putWord64le = tell . B.putWord64le
{-# INLINE putWord64le #-}
------------------------------------------------------------------------
-- | /O(1)./ Write a single native machine word. The word is
-- written in host order, host endian form, for the machine you're on.
-- On a 64 bit machine the Word is an 8 byte value, on a 32 bit machine,
-- 4 bytes. Values written this way are not portable to
-- different endian or word sized machines, without conversion.
--
putWordhost :: Word -> Put
putWordhost = tell . B.putWordhost
{-# INLINE putWordhost #-}
-- | /O(1)./ Write a Word16 in native host order and host endianness.
-- For portability issues see @putWordhost@.
putWord16host :: Word16 -> Put
putWord16host = tell . B.putWord16host
{-# INLINE putWord16host #-}
-- | /O(1)./ Write a Word32 in native host order and host endianness.
-- For portability issues see @putWordhost@.
putWord32host :: Word32 -> Put
putWord32host = tell . B.putWord32host
{-# INLINE putWord32host #-}
-- | /O(1)./ Write a Word64 in native host order
-- On a 32 bit machine we write two host order Word32s, in big endian form.
-- For portability issues see @putWordhost@.
putWord64host :: Word64 -> Put
putWord64host = tell . B.putWord64host
{-# INLINE putWord64host #-}
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